Uhf timing system for participatory athletic events

ABSTRACT

A participatory athletic event timing system based on backscattering modulation in the UHF band and including wirelessly encoding writable data tags with participant&#39;s bib numbers or a calculated derivative thereof for timing participants in a participative athletic event, and attaching the data tags to the participant&#39;s bibs for distribution of the bibs and data tags to participants so as to eliminate the need for matching data tags with bibs and maintaining the sequenced order of the matched data tags and bibs. In a preferred embodiment, when participants register for the event, they are assigned an ID number and a bib printed with that number and having attached to the bib one or more data tag encoded in the tags memory the ID number or a calculated derivative thereof. Before the start of the event, the athlete pulls the data tag from the bib and attaches it to their shoe. Antennas suitably designed and adapted for use with the data tags in participative athletic events are used to communicate with the data tags.

This is a continuation-in-part of U.S. application Ser. No. 12/077,490,filed Mar. 17, 2008, which claims the benefit of U.S. ProvisionalApplication No. 60/936,740, filed Jun. 22, 2007, the specifications ofwhich are hereby incorporated by reference.

BACKGROUND OF THE INVENTION

This disclosure relates to the design and development of a newparticipatory athletic event timing system based on backscatteringmodulation in the UHF band and to encoding wireless data tags such asradio frequency identification (RFID) tags with informationcorresponding to respective athletic event participants.

Participatory athletic events as used herein refer generally to eventsinvolving people who pay an entry fee to participate in an athleticevent which attempts to provide accurate course completion times to theparticipants. In such events, each athlete typically wears a timing chipon his or her body, most commonly on the athlete's ankle or shoe. Astypically used, the timing chip uniquely identifies the participant asthey cross strategically placed, electronic mats.

Finish-line mats may be used to provide each participant a “gun time”which is the time between the start of the race and the time that theparticipant crosses the finish-line mats. In addition to mats at thefinish line, large races (where it may take a particular participantseveral minutes to reach the starting line after the official “gun”start of the event) often have mats at the starting line as well so asto provide each participant with a “net” or “chip” time, which is theamount of time that the participant spent between the starting-line andfinish-line timing mats. Yet additional mats may be placed along theevent course to provide each participant with split times.

Existing chip timing systems generally include a timing chip thatcarries its own identification number and electronic mats that energizethe chip. The chip, which includes electronic circuitry and an energyreceiving coil, is typically encased within a glass or plastic innershell, which is then housed in another plastic outer case. The innershell is typically weatherproof, which allows for the chip to be worn invarious inclement weather conditions. Such chips are referred to as“passive” chips because they do not contain batteries (as do “active”chip designs), and such chips may be reused over and over again.

The chip includes a transponder which is passive and sends no signalsuntil it is placed within the magnetic field created by “energizing”antennas in the timing mats. The magnetic field energizes the coilwithin the chip, which produces an electric current and powers thechip's transponder. The transponder thereafter sends a signal, typicallyeither in a low frequency (LF) (i.e. under 135 kHz) or high frequency(HF) (i.e. 13.56 MHz), including its own unique identification code, andthis signal is captured by the “receive” antennas in the mat, and thencollected by a computer.

Existing timing chips typically comprise a Read Only Memory (ROM) typeRFID tag having its identification code stored in the RFID tag's ROM.The ID code inside the tag is encoded during the manufacture of the tagand is permanent and unchangeable for the life of the RFID tag. For atleast this reason an association process is always required when usingROM based tags, where the internal ID of the ROM based RFID tag must beassociated or matched up with an event participant identification number(or racing bib number).

The association process is a very time consuming process in which eachathlete's name and assigned identification or bib number is matched witha ROM based RFID tag or “chip.” The association information is neededwhenever the chip ID code is needed. For example, when an athletecrosses over a detector antenna (or RFID reader/interrogator), theinternal ID code of the chip is recorded by a reader and in a secondstep, the ID must then be cross-referenced to find the athlete's bibnumber and name. The cross-referencing information needed for this,however, must first have been compiled in advance of and in preparationfor the athletic event. To accomplish this compilation ofcross-referencing information, the chips need to be matched up with bibnumbers while maintaining the sequential order of both in relation toone another. As will be described in greater detail below, the time andresources needed to compile the cross-referencing information aresubstantial. As a result, the association process required by ROM basedtiming chips is a significant cost-driver for participatory athleticevents in terms of time, money, human labor, and patience.

FIG. 1 provides an example of a common method of sequencing andassociating the ROM based chips in preparation for an athletic event. Inthis example, a group of chips or tags 134 are first randomly sequencedat one end 104 of a wire 106 or cable or something else that could berun through holes in the packaging of the tags so that the order of thetags is not disturbed while laced through this line. A table-top antenna120 is used to read the chip ID's one at a time. For example, the nexttag 108 taken from the group of tags 134 may be slid across thetable-top antenna 120 in a direction 116 from one end 104 of the line106 to the other end 102. A laptop computer 122 may be used to controlthe table-top antenna 120 (to provide interrogator/reader functionalitywhen connected 124 with the table-top antenna 120). As the tag 108passes over the antenna 120, the tag's ID code is captured and stored bythe computer 122. Some kind of lookup table, spreadsheet, database, orother cross-referencing document must be created to maintain informationfor determining which tag ID codes have been associated with which bibnumbers.

The order in which the tag ID codes are stored must be maintained by thecomputer 122, and the sequential order of the tags as they are processedmust be maintained as well. For instance, all the tags on the line 106must be maintained in the same sequential order so that they may bematched up (either in real time as the tags are read and sequenced inthe computer 122 or at a later time) with a group of participantidentification numbers or bib numbers 136. The first three tags 110,112, 114 to be sequenced, for example, are stored in order in thecomputer 122 and associated with the first three bib numbers 126, 128,130 in the group of bib numbers 136. The next tag ID code stored insequence is then matched up with (or associated with) the next bibnumber in the stack of bib numbers 136, and this is repeated until thelast ordered bib number 132 in the group of bib numbers 136 isassociated with a tag sequenced on the line 106.

Any disruption in the sequence in either the tags along the line 106 orin the stack of bib numbers 136 may cause a mismatch between the bibnumber and the ID code of the chip. Once detected, considerable effortsmust be made by event organizers and event managers to reprocess thetags and bib numbers, which basically requires repeating the entireassociation process described above for matching up specific tags (withtheir particular ID codes) and bib numbers. If undetected, an incorrecttime could get assigned to some or all event finishers.

Tedious processes such as the above are repeated for millions ofathletes every year, and there are thousands of events in North Americathat utilize this or a similar method of associating RFID tags toparticipant bib numbers every year. Not only is there a significantamount of human labor required for sequencing and associating the ROMbased timing chips before an event, additional labor is required forcollecting and processing of the chips after the event for their reusein subsequent events.

Improved methods and systems are therefore needed to address these andother problems with existing participatory event timing. Prior to thepresent inventor's discoveries and the implementations of systems andmethods using his improvements, such improved methods and systems wereunknown.

BRIEF DESCRIPTION OF THE SEVERAL DRAWINGS

For a more complete understanding of the present invention, the drawingsherein illustrate examples of the invention. The drawings, however, donot limit the scope of the invention. Similar references in the drawingsindicate similar elements.

FIG. 1 illustrates tag sequencing and associating conventional RFID tagswith bib numbers.

FIG. 2A is an exemplary magnetic coupled reader and wireless data tag.

FIG. 2B is an exemplary electromagnetic coupled reader and wireless datatag.

FIG. 3 is an exemplary bib with at least one encodable wireless data tagattached to the bib.

FIG. 4 is an exemplary athletic event participant wearing multipleencodable wireless data tags.

FIG. 5A is an exemplary system of antenna lines for a participatoryathletic event.

FIG. 5B is an exemplary arrangement of antenna elements forming anantenna line such as those illustrated in FIG. 5A.

FIG. 5C is a side view of two exemplary antenna elements and radiationcharacteristics thereof.

FIG. 5D is a side view of two exemplary customized antenna elements andradiation characteristics thereof.

FIG. 5E is an end view of one of the antenna elements shown in FIG. 5Dand radiation characteristics thereof.

FIG. 5F is a perspective view of the two antenna elements shown in FIG.5D and radiation characteristics thereof.

FIG. 6 is an exemplary system for printing bib numbers and encoding datatags attached to the bib numbers.

FIG. 7 is an exemplary system for printing bib numbers, encoding datatags, and attaching the encoded data tags to the bib numbers.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

In the following detailed description, numerous specific details are setforth in order to provide a thorough understanding of the preferredembodiments. However, those skilled in the art will understand that thepresent invention may be practiced without these specific details, thatthe present invention is not limited to the depicted embodiments, andthat the present invention may be practiced in a variety of alternateembodiments. In other instances, well known methods, procedures,components, and systems have not been described in detail.

Although the present invention is primarily described in the context ofa running event, the methods and systems described may also be used inany other participatory athletic event or other event where wirelessdata tags may be worn by a person or attached to the person's gear (i.e.bike, helmet, canoe, shoe) and used for timing the person in an event oractivity or for tracking the person or the person's gear before, during,and/or after the event or activity. Further, although variousembodiments are described using various technologies such as, forexample, ultra high frequency (UHF) wireless data tags, the presentinvention is not limited to such technologies, and various aspects ofthe invention are independent of the specific technologies described.

RFID systems may be discussed generally in terms of lower frequencysystems operating under 100 MHz and higher frequency systems operatingabove 100 MHz. Lower frequency systems generally include readers andtags which utilize magnetic coupling and operate in LF (under 135 kHz)or HF (13.56 MHz) frequencies. An exemplary lower frequency system 200is shown in FIG. 2A and includes an interrogator/reader 202 and a tag218. The reader 202 may include an integrated circuit (IC) which sendssignals to an oscillator 206 creating an alternating current in thereader's coil 212. The current generates an alternating magnetic fieldthat effectively provides power 214 for the tag 218. The magnetic fieldfrom the reader's coil 212 interacts with a coil 216 in the tag 218which induces a current in the tag 218. The induced current causescharge to flow into a capacitor 220, and the charge is trapped by adiode 222. The charge accumulates in the capacitor 220 until the voltageis sufficient to activate an IC 224, which thereafter transmits the IDcode of the tag that is stored in the ROM or memory. The highs and lowsof the digital signal from the IC 224 turns on and off a transistor 226,which results in variation in the resistance of the tag's circuitrycausing generation of a varying magnetic field which in turn interactswith the reader's coil 212. Using a technique referred to as loadmodulation, the magnetic fluctuations cause changes in the flow ofcurrent in the reader's coil 212 in the same pattern as the highs andlows (ones and zeros) transmitted by the tag 218. An analog-to-digitalconverter 210 changes the variation in current flowing through thereader's coil 212 into a digital signal for an IC 208 in the reader 202that effectively receives the transmitted tag ID code 226.

By contrast, higher frequency systems generally include readers and tagswhich utilize electromagnetic coupling and operate in UHF (from 860 MHzto 930 MHz) or Microwave (from 2.45 GHz to 5.8 GHz) frequencies. Anexemplary higher frequency system 250 is shown in FIG. 2B and includesan interrogator/reader 252 and a tag 268. The reader 252 may include anIC 254 which sends a digital signal to a transceiver 256, whichgenerates an analog RF signal that is transmitted by a dipole antenna260. The electric field of the propagating signal from the dipoleantenna 260 creates a potential difference across the tag's dipoleantenna 266. The circuitry within the tag 268 is sometimes discussed interms of RF front end circuitry 270 and analog/digital circuitry 272.Within the RF front end circuitry 270, current caused by the potentialdifference across the tag's dipole antenna 266 flows into a capacitor,and the charge is trapped by a diode. The charge accumulates in thecapacitor until the voltage is sufficient to activate an IC in theanalog/digital circuitry 270, and the IC thereafter transmits the IDcode of the tag as a digital signal back into the RF front end circuitry270. The highs and lows of the transmitted signal turn on and off atransistor in the RF front end circuitry 270, and this turning on andoff of the transistor causes the tag's antenna 266 to alternatelyreflect back or absorb some of the incident RF energy received from thereader 252. In a technique referred to as backscatter modulation,variations in the amplitude of the reflected signal correspond to thepattern of the turning on and off of the transistor in the RF front endcircuitry 270. The reader's transceiver 256 detects the reflectedsignals and converts them into a digital signal for the reader's IC 254for determination of the tag's transmitted ID code.

Other components may be included in the readers and tags described inFIGS. 2A and 2B. Components may be combined or integrated into fewerintegrated components or separated. With regard to the higher frequencytags, for example, the combination of the RF front end circuitry 270 andanalog/digital circuitry 272 is sometimes referred to as thesemiconductor or integrated circuit portion of the tag, to which isattached a small antenna 266. The higher frequency systems preferablyinclude writing circuitry in the reader 252 and writable memory in thetag 268.

Class 1 Gen 2 RFID tags operate in the UHF range of 900 MHz to 928 MHzand are more susceptible to RF energy being absorbed by the water.Consequently, tags operating within this frequency range have not untilnow been investigated for utilization in applications such asparticipative athletic events where the human body may be in closeproximity to the transmitted signal from the RFID tag. Although the trueresonant frequency for excitation of water molecules in human tissue isnear 2.5 GHz, there is still considerable absorption by the humantissue. Within the UHF frequency range, the present inventor found thatthe closer a tag is to the human body, the more likely its energy willbe absorbed by the body. The present inventor discovered that aseparation of at least one (1) inch or proper shielding is required toprevent excessive absorption into the human body. The present inventorfurther discovered new and innovative solutions, which are discussedfurther below, to address the energy absorption and other problems.

Initial testing involved a reader and two antennas from an RFIDequipment supplier, Impinj, to test the viability of using UHF RFIDtechnology in timing participatory athletic events. Because UHF systemswere widely believed to be infeasible for use in timing participativeathletic events, the sentiment among participatory athletic eventmanagers and organizers was completely against such testing. Until thepresent inventor's efforts, the industry firmly believed that lowerfrequencies work best for use near the human body. Skeptics warned thatat UHF frequencies, the low level energy returned from the tag would beabsorbed by the athlete's body, and neither the sensitivity nor a properrange would be available to obtain an accurate read of the ID codeinside the UHF tag.

Initial testing started with a set of passive Class 1 Gen 2 tags from anRFID tag supplier, Avery Dennison. As with passive RFID tags generally,the passive Class 1 Gen 2 tags do not have an internal power source.When the tag passes through an RF energy field which is tuned to thefrequency of the tag's receiver, the tag powers on and transmits itsinternal ID code. The reader antennas switch between interrogation andtransmission, and during the interrogation phase the reader antennasreceive the information transmitted by the tag.

Unlike other passive tags, Class 1 Gen 2 tags include writable memoryinto which data can be wirelessly encoded. The present inventordiscovered that the association process tied to ROM based timing chipsand subsequent collection and reprocessing of existing bulky andexpensive RFID tags can be eliminated by writing the athlete's bibnumber into the tag memory, utilizing low cost read/writable tags, andattaching the tags on the athlete's bib. Disposing these tags at the endof the event is a cost issue related to the relative costs (i.e.economics) of collection and re-processing. If disposing the tags isless expensive than re-collection and re-processing, then it is moreeconomical to issue new tags with every event. With this in mind, theinventor set out to discover improved methods and systems havingsufficient reliability and improved costs so as to allow for widespreaduse in timing participative athletic events.

Although other types of wireless encodable data tags may be used, Class1 Gen 2 tags are preferred in part because such tags are read/writeable,can be made to be physically very small and light weight, and can bemanufactured in very high volumes (thus, lowering acquisition costs andallowing the tags to be disposable). The present inventor determinedthat light weight Class 1 Gen 2 tags tend not to be felt by the athleteswhen they flap around. Class 1 Gen 2 tags can be adapted for use inlight weight packages and paper form factors. Preferably, the wirelessdata tags have a paper form factor, an omni-directional antenna, and avery light weight (preferably less than one (1) ounce).

In testing, a set of 50 Avery-Dennison AD 622 tags were encoded suchthat the first 10 digits of the 96 bit EPC code in the tags were thesame as the numbers on the bibs that the tags were attached to. Theremaining digits were made into trailing zeros. For example, runner#2711's tag ID was encoded as:)

xxxx xxxx xxxx xx00 0000 2711

The x can be any hexadecimal digit between ‘0’ and ‘F’. The encoding isin groups of 4 bits, and each grouping is represented by a hexadecimaldigit. Only the decimal representation of the bib number was encodedinto the tag memory. Therefore no conversion from hexadecimal to decimalwas necessary. In the above example the 1, 1, 7, and 2 were not treatedas hexadecimal numbers but as decimal numbers.

FIG. 3 shows a race bib 300 according to one embodiment. The bib 300comprises a printed race number 310 and at least one wireless encodabledata tag 320 attached to the bib 300. The race number 310 or amathematical representation of it is written to the memory of each ofthe data tags 320.

The race number 310 as shown in FIG. 3 is “M1000” but can be any number,such as “2711” as described above or any other combination ofalphanumeric or other symbols. Preferably, the race number 310 comprisesonly numbers so that, as discussed above, the exact race number may bewritten to the memory of the data tags 320 so that the ID codes forthose tags 320 include the exact race number 310. If the race number 310includes alphabetical characters, as shown in FIG. 3, then the alpacharacters such as the “M” in the race number 310 shown may berepresented, for example, by an extra digit written to each tag'smemory. For example, for bibs having the “M” prefix (perhaps designatinga “male division” of athletic participants) runner #M1000's tag ID maybe encoded as:)

xxxx xxxx xxxx xx00 5000 1000

An example tag ID code that has the following mathematical relationshipto the runner #M1000:

“tag ID code=(offset of 5000 0000 for “M” prefix)+(numeric part of bibnumber)+(arithmetic offset of 1)”

resulting in the following tag ID code:)

xxxx xxxx xxxx xx00 5000 1001

Preferably, the tag itself is encoded with the same number that appearson the bib. However, any reversible process such that the bib number canbe determined from the encoded tag number, and vice versa, may be usedhere. Preferably, the tag is encoded with a tag ID code (or identifier)so that either the tag ID code can be used to determine the bib numberor the bib number can be used to determine the tag ID code, without theuse of a lookup table or database for cross-referencing between the bibnumber and the tag ID code.

Having the athlete bib number encoded into the tag so that the samenumber is used both visually on the bib and electronically in the RFIDtag not only eliminates a tremendous amount of labor associated withevent preparation before the event but also streamlines the datamanagement aspects of the overall system. Preferably, event organizersuse participant bibs, each having at least one passive RFID tag attachedto the bib and encoded to have the bib number in its writable memory, toavoid having to match each bib with a particular RFID tag. Whenparticipants register for the event, they are assigned an ID number anda bib printed with that ID number and having attached to the bib one ormore RFID tags encoded with that same ID number. Before the start of theevent, the athlete simply pulls the RFID tag from the bib and attachesit to their shoe (or ankle bracelet).

Preferably, the data tags 320 each comprise a UHF tag 268 as in FIG. 2Band is attached to the bib 300 so that it may be peeled off and lacedthrough shoe laces. For example, tag 332 may be attached to the bib 300with a mild adhesive that is strong enough to retain the tag 332 fordistribution of the bib 300 with attached tag 332 to a participant yetweak enough to allow the tag 332 to be easily detached. A small hole 336or other features may be included in the tag 332 to allow forreattaching the tag 332 to a shoe.

In one embodiment, the tag 332 can be peeled from the bib 300 and simplystuck to a shoe or other article such as an ankle bracelet or helmetusing adhesive on the tag 332. In one embodiment, a tag 330 may beattached to the bib 300 so that detachment of the tag 330 may beaccomplished by ripping the portion of the bib 300 along perforations334. The separated portion with the tag 330 may then be attached to ashoe's laces using a hole 338. Other methods may be used to attach thetags 320 to the bib 300 for distribution to event participants so thatthe tags may be removed and reattached elsewhere for use during theathletic event.

In one embodiment, deployment of the wireless encoded data tags may beaccomplished by having each athlete remove the tag from the bib andplace the tag on athlete's shoe. This method has advantages. First, theathlete's shoe acts as a shield between the human foot and the tag,consequently improving communications with the tag (i.e. improvingreadability of the tag). Second, the shoe is in close proximity with adetector or reader antenna positioned as a timing mat on the ground,again consequently improving communications with the tag. Further, themostly bone construction of the foot provides additional shielding (ascompared with other locations on the athlete).

In one embodiment, deployment of the wireless encoded data tags may beaccomplished by having each athlete keep the tag on the bib itself.

FIG. 4 shows an exemplary event participant 400 wearing a bib 410 andseveral tags 420. Preferably, the RFID tags 420 are attached to the bib410 when the participant 400 picks up the bib 410 and other eventmaterials prior to the event. Prior to the start of the event, theparticipant 400 may detach some of the tags and reattach them to shoes430, clothing, or other articles such as wrist 438 or ankle 432 straps,helmets 436, bicycles, boats, and clothing articles or sportingequipment. Although the preferred location when a single timing tag isused is on the shoe 430 or ankle 432, keeping the tag on the bib itselfwas tested and is possible, however requires further development andtesting. Tags on bibs or tags on wrists may be effective in pre- orpost-event activities where tag readers may be suitably positionedproximate to the tags. For example, prior to some events participantsmay be invited to a carbohydrate (carbo loading) meal. The participantsmay wear a tag on their wrist so as to allow verification and entry ofthe participants for the meal, perhaps with event organizers usinghandheld readers or a table-top reader 120. Likewise, waiting lines forpost-event activities may be reduced if the participant's bib 410includes a wireless data tag 434 attached to it and event managers usehandheld readers or suitably pole mounted readers to verify admissioninto the post-event activity areas.

Also shown in FIG. 4 is a hat or helmet tag 436. In one embodiment, abicycle helmet tag 436 is used for tracking the helmet before, during,and after an event such as a bike event in a bike race or a triathlon.For example, during the swim portion of the triathlon the bike helmetshould typically remain motion free within the transition area. Readersstrategically placed about the transition area may be used for trackingthe movements of such equipment. During the bike portion of thetriathlon, having a tag on the helmet may allow for improved read ratesas compared to chest located, bib attached tags because, like the shoelocated tags, the bony structure of the head provides some shielding.Moreover, helmet located tags are farther from the metallic mass of thebicycle frame, thus likely improving read rates as compared to chestlocated tags.

FIG. 5A shows an exemplary system 500 of antenna lines for aparticipatory athletic event according to various embodiments. In aparticipatory event such as a running event, the participants 502 aretimed as they run from a starting line to a finish line. Finish linetiming mats may comprise a primary line of antennas 514 having a matlength 522 that spans the width of the running course and having a matwidth 518 that runs along the lengthwise direction of travel on therunning course. A secondary line of antennas 512 spaced apart from theprimary line 514 provides a backup to the primary line 514. Startingline timing mats may comprise a single antenna line 504 or may comprisea pair of antenna lines as shown for the finish timing. As a particularrunner 520 crosses over the starting line timing mat 504 the runner'swritable RFID tag is interrogated/read by the interrogator/reader 506controlling the starting line antenna line 504, and a starting time forthe runner 520 is determined.

Software used by the event managers and organizers coordinates theinterrogators/readers 506, 508, 510 controlling their respective antennalines 504, 514, 512, and as the runner 520 crosses over the finish linemats 514, 512 a net (or chip) time is computed for the runner 520, wherethe net time is the difference between the starting time and finishingtime for runner 520. Gun time may also be computed, which is the timebetween the first start of the event and the time when the runner 520crossed the finish line. Various algorithms may be used to control theinterrogators/readers to calculate net and gun times, to deal withmultiple RFID tags contending for transmitting their tag ID codes andexpected signal collisions in such multiple tag situations, to handlecomputations of times when multiple or backup antenna lines are used,such as with the secondary finish line mat 512 shown, and to rank orderfinishers according to time and other categories of participants.

The present inventor studied and tested various different configurationsof antennas and tags. Antennas were hung from poles in variety ofdifferent angles; they were placed on the ground; and they were used ina variety of different numbers. FIG. 5B is an exemplary arrangement ofantenna elements forming an antenna line such as the antenna line 514illustrated in FIG. 5A. Each antenna element 536, 538, 540 is positionedwithin a casing 530, 532, 534 and then positioned adjacent to oneanother across a width 522 of the path of travel of the eventparticipants to form the antenna line 514. For a particular athleticevent, more or less elements may be used, as required by the layout ofthe athletic event course.

The inventor discovered that commercially available antennas, such asthe antenna elements 584, 586 shown in FIG. 5C, in close proximity toone another create blind spots 592 where radiation patterns 590, 588from adjacent antennas 584, 586 create null fields. The inventor alsodiscovered that existing, commercially available antennas, althoughtypically producing excellent read rates when the tags were directlyover them, were designed for radiating energy upward into space directlyabove them instead of along the horizontal path of the athlete's motion.Consequently, the inventor determined that the lower the angle ofradiation from the horizon, the better the antenna was expected toperform. Cushcraft and Kathrein-Scala antennas were used in prototypesystems until the custom antennas were available and used in pilotevents. The custom antennas were designed to maximize the radiatedenergy along the athlete's path of travel. Kathrein-Scala antennas witha wide beam width were used widely for the first few pilots.

The term “dwell time” was coined by the inventor to describe the amountof time an athlete wearing a wireless data tag would have to spend in anUHF RF field created by the reader. Dwell time is the total time awireless data tag would have to spend in an energy field to absorbsurrounding RF energy and transmit its internal ID code. Inparticipatory sports, the fastest athletes may run at 12.5 miles perhour. The number of athletes who could run at this speed for prolongedperiods is few. Given a maximum speed expected of the athlete, one candetermine the horizontal width of the field required along the path ofathlete's travel so that enough RF energy is absorbed for the internalID to be sent back.

In one example, measurements taken indicated that tags may be re-read atintervals of about 25 msec. Within that span of time, defined as thedwell time, a runner traveling at 12.5 Miles per hour would move about0.14 meters. There is additional overhead time associated with thereader switching between transmit/read and switching between the antennaports that would add to the required dwell time. The exact dwell time isa function of the antenna port rotation, switching betweenread/interrogate of the reader, and the speed of the athlete. To be onthe conservative side, this distance was increased to 2.0 meters andused as an indicator of horizontal distance needed so that the tagremained within the RF energy field long enough to both receive enoughRF energy and respond back to the reader antenna with the tag's ID code.In this example, the reader rotates through the multiple antennasconnected to reader ports and only utilizes one antenna at a time for ashort burst of time. After each burst of time (which may be on the orderof 50 to 200 msec) the reader rotates to the next antenna while shuttingthe rest of the antennas off. The particular process that the readeruses to cycle through connected antennas is a function of algorithmsused in the software controlling the reader. Multiple methods of dataextraction and data storage in the reader were developed.

The inventor determined that there may be advantages to having twoantenna lines arranged in close proximity to one another in case thefirst line fails to receive and record the transmitted athlete ID. Usingtwo antenna lines, if the initial antenna line fails to provide anaccurate read, the secondary antenna line placed in close proximitywould enhance the probability of capturing the data tag's internal ID. Astatistical approximation for overall read rate as a function ofindividual read rates per antenna line is provided in Table 1 below.

FIGS. 5D, 5E, and 5F show exemplary customized antenna elements and thepreferred radiation characteristics thereof for use in a participatoryathletic event timing system based on backscattering modulation in theUHF band. Custom antennas are preferred for a UHF based participatoryathletic event timing system. Commercial antennas tend to have anarrower beam and are designed to provide an adequate range for in anarrower region of space than is desired for athletic event timingsystem antennas.

The present inventor determined that the antenna elements 530, 538 (asshown in FIG. 5D) are each preferably placed in protective casings 536,532 to both weather proof the antenna and to protect it from therepeated pounding of the runners going over it. Preferably, the antennaelement is designed to provide a uniform radiation pattern hovering overthe road surface in a rectangular shape, as depicted in FIGS. 5D, 5E,and 5F. The width 550, 552 of the radiation pattern is lined upperpendicular to the direction of travel 566 by the runners or eventparticipants. The length of the field is along the direction of therunners travel 566 and should be long enough to meet the dwell timespec. This spec is the required time for a tag to stay in the field toturn on and transmit its ID back to the interrogating antenna.

In one embodiment, the width 550, 552 of the radiation field may be 3 or4 feet wide. A casing of the same size is preferably used so that theantenna line may be easily setup by placing adjacent casings side byside, as depicted in FIG. 5B, across the entire width of the street orpath of event participants. The present inventor discovered that sizingthe antenna casing 530 to match the width of field 550 of the antennaelement 536 (by cutting the casing 530 or includes ends 554, where theradiation pattern drops off) allows for simple end to end placement ofadjacent antenna casings 530, 532 (i.e. where ends 554 of adjacentantennas may be touching one another or where any space 558 betweenadjacent ends 554 is negligible). The antenna casing 536 is preferablyas thin as possible, perhaps with a thickness 560 of 1 inch or lessabove the road surface so as to minimize obstructions in the path ofevent participants.

The radiation pattern of custom antennas are preferably uniform and havesharp drop offs at the ends 554 of the antenna casings, as shown in FIG.5D, so that adjacent casings placed side by side result in minimalinterference between adjacent antenna radiation patterns. The radiationpattern of custom antennas along the direction of the participantstravel 566 are also preferably uniform. FIG. 5E depicts a side view of acustomized antenna with the desired radiation pattern. In oneembodiment, for several feet before 562 and after 564 the actual element530, a passive RFID tag would enter the field of the antenna and spendsufficient time in there to power up and transmit its ID back.Preferably, the antenna element 530 is designed to provide a radiationpattern hovering to a height 568 of at least 1 foot above the roadsurface (or above the antenna element 530 or above the antenna casing536). FIG. 5F is a perspective view showing preferable antenna radiationpatterns for to side by side customized antennas 530, 532. The radiationpatterns in both length of field 556 and width of field 550, 552 arepreferably uniform and have sharp drop offs (i.e. step function) alongthe edges.

The uniformity of radiation in the width of field 550, 552 direction (asin FIG. 5D) is preferred to avoid creation of dead spots 592 as shown inFIG. 5C. FIG. 5C depicts a commercial antenna radiation pattern with anarrow radiation field pattern. Overlap of the radiation field can alsolead to creation of constructive and destructive radiation fields andhence lead to dead spots 592 due to destructive cancellation of thefield. Efforts to minimize dead spots 592 between adjacent antennaelements 584, 586 may include attempts to space apart adjacent antennacasings 580, 582, requiring trial and error and guessing on the part ofevent organizers and still does not result in uniform radiation patternsor radiation patterns of sufficient width 550 and length 556.

FIG. 6 is an exemplary system for printing bib numbers and encoding datatags attached to the bib numbers. In one embodiment, as shown, RFID tags610 are attached to bibs 600 before bib numbers 620 are printed on thebibs and also before the tags are encoded (i.e. written to) with theirtag ID's. The bibs with attached tags are then fed through an inkprinter 630 that prints the bib numbers 620 on the bibs. The bibs withunencoded tags are then passed through an RFID printer 640 that writes(or encodes) the bib numbers into the tag memories. The ink printer 630and the RFID printer 640 print and write the bib numbers in the samesequence, starting from the same number. Following the writing/encoding,the bibs are separated from one another along the creases orperforations 650.

Those skilled in the art will immediately appreciate that the particularorder of method steps performed may be changed and that certain stepsmay be combined if, for example, equipment becomes available for suchcombination. For example, the RFID printer 640 may encode the tags 610before running through the ink printer 630 so that the bibs 660 emergingfrom the ink printer 630 are fully prepared bibs having encoded RFIDtags attached, ready for separation along perforations betweensuccessive bibs and distribution to event participants. As anotherexample, the function of the ink printer 630 may be combined with thefunction of the RFID printer 640 so that bibs without printed bibnumbers but with attached tags may be passed through a singledintegrated ink printer/RFID printer (not shown). The bibs 660 emergingfrom such an integrated or combined ink printer/RFID printer are fullyprepared, ready for separation and distribution to event participants.

FIG. 7 is an exemplary system for printing bib numbers, encoding datatags, and attaching the encoded data tags to the bib numbers. The bibs700 preferably comprise a tear resistant, water proof paper capable ofrunning through an ink printer 730. Once the bib number 720 is printedon the bib 700, it is fed through tag attaching device 750 that removeseach tag previously encoded by RFID printer 740 from a tag backingmaterial 760 and attaches the encoded tag 710 to the printed bibs 774.The sequence of printed bibs 774 and encoded tags 710 are matched sothat the bibs 770 emerging from the tag attaching device 750 are fullyprepared bibs 770 having encoded RFID tags attached, ready forseparation along perforations 772 between successive bibs anddistribution to event participants.

As with the printing processes described for FIG. 6, the particularorder of method steps performed may be changed and that certain stepsmay be combined if, for example, equipment becomes available for suchcombination. For example, the RFID printer 740 may follow the tagattaching device 750 instead of preceding it as shown. Likewise the inkprinter 730 may follow the tag attaching device 750 instead of precedingit as shown. Or both the RFID printer 740 and ink printer 730 may followthe tag attaching device 750 instead of preceding it as shown. Alsosimilar to the processes described for FIG. 6, any of the devices shownmay be combined to perform any or all of the functions required. Forexample, the tag attaching device 750 may comprise a combined RFID andink printer that receives as its inputs blank bib paper 700 andunencoded RFID tags 710 on a backing material 760 and yields as itsoutput fully prepared bibs 770 having encoded RFID tags attached, readyfor separation along perforations 772 and distribution to eventparticipants.

Pilot Testing

Falmouth Road Race, Aug. 12, 2007: Two different antenna lines of 28 ftwide were constructed utilizing the UHF Impinj readers. Each reader hadenough ports to connect to 4 antennas. One of the antenna lines was setflat on the street near the start of the event and a second line wassetup near the 3 mile mark of the event. The second line used antennasmounted on poles to test the read rate for RFID tags attached to theathlete's racing bibs (referred to as “chest tags” or “bib tags”).

The bibs for this event included two sets of tags, the AD 622 and the AD222, which were both attached to bibs. The AD 622 tags were kept on thebibs, but the athletes were asked to peel the AD 222 tags from theirbibs and use the hole that was inserted into the side of the AD 222 totie the tag into their shoe laces. The encoding of the tags wasperformed so as to allow readers to distinguish between which one of thetwo Class 1 Gen 2 RFID tags on an athlete was being read. Primary timingfor the event used ChampionChip conventional ROM based readers and tags(i.e. lower frequency, magnetic coupling type systems), and the UHFsystems and methods were used for pilot testing only.

The results of the pilot were mixed and uncertain. Many athletes didn'tbother with the request to reattach the AD 222 tags to their shoes(referred to as “shoe tags”). The bib tags were worn by all athletes,but the shoe tags were tied into shoe laces by only a fraction of theathletes. The antennas laid down on the road were able to read the IDsof about 60% of the bib tags worn by athletes. But the road antennaswere meant for the shoe tags and not the bib tags. The second set ofantennas that were mounted on poles and meant to read the bib tag didnot read more than about 50% of the bib tags.

Read rates were lower than expected because wearing of the shoe tags byathletes was not enforced by the event managers, and the pole antennaswere not adequate for proper reading of bib tags, which were in closeproximity to the athlete's chest.

Chicago Half Marathon, Sep. 9, 2007: Although chest (i.e. bib) tags werealso printed on the bibs, only shoe tags were read in this pilot. Theshoe tags were delivered to the event attached to the bibs, and theathletes were asked to peel off and reattach their tag to their shoe bylacing their tag through their shoe laces. Two separate lines of UHFantennas were laid down on the street for data collection. The primarysystem for timing the event again used ChampionChip conventional ROMbased readers and tags, and the UHF systems and methods were used forpilot testing only.

A much higher number of athletes put their shoe tag on as requested,and, consequently, the read rate was higher than the prior pilot. Atotal of 8,289 unique reads were captured. The actual number offinishers in the Chicago half marathon was 10,118. The read rate for asingle antenna line was: 0.8192 (8,289/10,118), or 81.92%. The exactnumber of runners who wore their shoe tags is not known. Based on theread rates, overall read rates for two separate antenna lines in closeproximity (i.e. 12 feet apart) were determined. The requested targetoverall read rate was 98%.

A statistical approximation was used to determine the overall read ratesof two separate antenna lines in close proximity. This approximation isbased on a binomial distribution. In this calculation each antennaline's read rate is assumed to be an independent process and not afunction of a different line's read rate.

Our Assumptions:

-   -   Let N be the # participants in an event;    -   Let n be the number of athletes not identified by an antenna        line; and    -   Let p be the read rate per antenna line.

From the above assumptions, lets choose p=0.9. This read rate amounts to9 out of 10 participants being read over a single antenna line. Let'sassume there are 1,000 runners, so the first read would cover,1,000*0.9=900 participants; n=1,000−900=100. On the second read with anexpected average of 90%, an additional 100*0.9=90 runners are read. Atthis point the total number of runners read after the second read is at990 (900+90) or 99% of the field. Table 1, showing read rates versus thenumber of athletes was constructed to aid with determination of thenumber of antenna lines required.

TABLE 1 p = 0.80 p = 0.85 p = 0.90 p = 0.95 # athletes 1st Read OverallRead 1st Read Overall Read 1st Read Overall Read 1st Read Overall Read100 80 96 85 97.75 90 99 95 99.75 500 400 480 425 488.75 450 495 475498.75 1000 800 960 850 977.5 900 990 950 997.5 3000 2400 2880 25502932.5 2700 2970 2850 2992.5 5000 4000 4800 4250 4887.5 4500 4950 47504987.5 7500 6000 7200 6375 7331.25 6750 7425 7125 7481.25 10000 80009600 8500 9775 9000 9900 9500 9975 15000 12000 14400 12750 14662.5 1350014850 14250 14962.5 20000 16000 19200 17000 19550 18000 19800 1900019950

For this pilot, using off-the-shelf UHF antennas, the overall read ratesof two antenna lines was very conservatively estimated to be near 95%read rates, even when it was certain that not all runners put their shoetags on. Customized antennas were expected for subsequent pilots andwere expected to improve the read rate of each line by a few percentagepoints.

Detroit Marathon, Oct. 21, 2007: Customized antennas were used in thispilot. The supplier's antenna elements were used in one complete 28 footline of antennas laid across the width of the running path. The primarysystem for timing the event again used ChampionChip conventional ROMbased readers and tags, and the UHF systems and methods were used forpilot testing purposes only.

Results of this pilot were very successful and met all targets,requirements, and objectives. The custom antenna read rates were betterthan the commercially available, off-the-shelf antennas used in priorpilots. Consequently, the present inventor's timing methods and systemsusing the UHF Class 1 Gen 2 tags and UHF antennas were deemed successfulby the event managers and organizers. The present inventor's timingmethods and systems were subsequently used at the Philadelphia Marathon,Las Vegas Marathon, and other premier events as the primary and the onlytiming system.

The terms and expressions which have been employed in the forgoingspecification are used therein as terms of description and not oflimitation, and there is no intention in the use of such terms andexpressions of excluding equivalence of the features shown and describedor portions thereof, it being recognized that the scope of the inventionis defined and limited only by the claims which follow.

1. A method of using wireless data tags in a participatory athleticevent timing system, the unordered method steps comprising: wirelesslyencoding at least one wirelessly writable and wirelessly readable datatag with information uniquely associating said at least one data tagwith at least one participant bib; and attaching said at least one datatag to said at least one participant bib. 2.-19. (canceled)